Effective Elastic and Neutron Capture Cross Section Calculations Corresponding to Simulated Fluid Properties from CO2 Push-Pull Simulations
The submission contains a .xls files consisting of 10 excel sheets, which contain combined list of pressure, saturation, salinity, temperature profiles from the simulation of CO2 push-pull using Brady reservoir model and the corresponding effective compressional and shear velocity, bulk density, and fluid and time-lapse neutron capture cross section profiles of rock at times 0 day (baseline) through 14 days.
First 9 sheets (each named after the corresponding CO2 push-pull simulation time) contains simulated pressure, saturation, temperature, salinity profiles and the corresponding effective elastic and neutron capture cross section profiles of rock matrix at the time of CO2 injection. Each sheet contains two sets of effective compressional velocity profiles of the rock, one based on Gassmann and the other based on Patchy saturation model. Effective neutron capture cross section calculations are done using a proprietary neutron cross-section simulator (SNUPAR) whereas for the thermodynamic properties of CO2 and bulk density of rock matrix filled with fluid, a standalone fluid substitution tool by Schlumberger is used.
Last sheet in the file contains the bulk modulus of solid rock, which is inverted from the rock properties (porosity, sound speed etc) based on Gassmann model. Bulk modulus of solid rock in turn is used in the fluid substitution.
Citation Formats
TY - DATA
AB - The submission contains a .xls files consisting of 10 excel sheets, which contain combined list of pressure, saturation, salinity, temperature profiles from the simulation of CO2 push-pull using Brady reservoir model and the corresponding effective compressional and shear velocity, bulk density, and fluid and time-lapse neutron capture cross section profiles of rock at times 0 day (baseline) through 14 days.
First 9 sheets (each named after the corresponding CO2 push-pull simulation time) contains simulated pressure, saturation, temperature, salinity profiles and the corresponding effective elastic and neutron capture cross section profiles of rock matrix at the time of CO2 injection. Each sheet contains two sets of effective compressional velocity profiles of the rock, one based on Gassmann and the other based on Patchy saturation model. Effective neutron capture cross section calculations are done using a proprietary neutron cross-section simulator (SNUPAR) whereas for the thermodynamic properties of CO2 and bulk density of rock matrix filled with fluid, a standalone fluid substitution tool by Schlumberger is used.
Last sheet in the file contains the bulk modulus of solid rock, which is inverted from the rock properties (porosity, sound speed etc) based on Gassmann model. Bulk modulus of solid rock in turn is used in the fluid substitution.
AU - Chugunov, Nikita
A2 - Altundas, Bilgin
DB - Open Energy Data Initiative (OEDI)
DP - Open EI | National Renewable Energy Laboratory
DO - 10.15121/1452749
KW - geothermal
KW - energy
KW - CO2
KW - carbon dioxide
KW - push-pull
KW - active seismic
KW - well logging
KW - EGS
KW - neutron capture
KW - SNUPAR
KW - stimulation
KW - sensitivity analysis
KW - characterization
KW - fault
KW - fracture
KW - fluid
KW - brine
LA - English
DA - 2018/03/07
PY - 2018
PB - Lawrence Berkeley National Laboratory
T1 - Effective Elastic and Neutron Capture Cross Section Calculations Corresponding to Simulated Fluid Properties from CO2 Push-Pull Simulations
UR - https://doi.org/10.15121/1452749
ER -
Chugunov, Nikita, and Bilgin Altundas. Effective Elastic and Neutron Capture Cross Section Calculations Corresponding to Simulated Fluid Properties from CO2 Push-Pull Simulations. Lawrence Berkeley National Laboratory, 7 March, 2018, GDR. https://doi.org/10.15121/1452749.
Chugunov, N., & Altundas, B. (2018). Effective Elastic and Neutron Capture Cross Section Calculations Corresponding to Simulated Fluid Properties from CO2 Push-Pull Simulations. [Data set]. GDR. Lawrence Berkeley National Laboratory. https://doi.org/10.15121/1452749
Chugunov, Nikita and Bilgin Altundas. Effective Elastic and Neutron Capture Cross Section Calculations Corresponding to Simulated Fluid Properties from CO2 Push-Pull Simulations. Lawrence Berkeley National Laboratory, March, 7, 2018. Distributed by GDR. https://doi.org/10.15121/1452749
@misc{OEDI_Dataset_7177,
title = {Effective Elastic and Neutron Capture Cross Section Calculations Corresponding to Simulated Fluid Properties from CO2 Push-Pull Simulations},
author = {Chugunov, Nikita and Altundas, Bilgin},
abstractNote = {The submission contains a .xls files consisting of 10 excel sheets, which contain combined list of pressure, saturation, salinity, temperature profiles from the simulation of CO2 push-pull using Brady reservoir model and the corresponding effective compressional and shear velocity, bulk density, and fluid and time-lapse neutron capture cross section profiles of rock at times 0 day (baseline) through 14 days.
First 9 sheets (each named after the corresponding CO2 push-pull simulation time) contains simulated pressure, saturation, temperature, salinity profiles and the corresponding effective elastic and neutron capture cross section profiles of rock matrix at the time of CO2 injection. Each sheet contains two sets of effective compressional velocity profiles of the rock, one based on Gassmann and the other based on Patchy saturation model. Effective neutron capture cross section calculations are done using a proprietary neutron cross-section simulator (SNUPAR) whereas for the thermodynamic properties of CO2 and bulk density of rock matrix filled with fluid, a standalone fluid substitution tool by Schlumberger is used.
Last sheet in the file contains the bulk modulus of solid rock, which is inverted from the rock properties (porosity, sound speed etc) based on Gassmann model. Bulk modulus of solid rock in turn is used in the fluid substitution.
},
url = {https://gdr.openei.org/submissions/1018},
year = {2018},
howpublished = {GDR, Lawrence Berkeley National Laboratory, https://doi.org/10.15121/1452749},
note = {Accessed: 2025-05-04},
doi = {10.15121/1452749}
}
https://dx.doi.org/10.15121/1452749
Details
Data from Mar 7, 2018
Last updated Jun 14, 2018
Submitted Mar 7, 2018
Organization
Lawrence Berkeley National Laboratory
Contact
Curtis Oldenburg
510.486.7419
Authors
Original Source
https://gdr.openei.org/submissions/1018Research Areas
Keywords
geothermal, energy, CO2, carbon dioxide, push-pull, active seismic, well logging, EGS, neutron capture, SNUPAR, stimulation, sensitivity analysis, characterization, fault, fracture, fluid, brineDOE Project Details
Project Name Push-pull well testing using CO2 with active source geophysical monitoring
Project Lead Sean Porse
Project Number EE0001554